CN105301463A - Unmanned plane insulator zero measurement device - Google Patents
Unmanned plane insulator zero measurement device Download PDFInfo
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- CN105301463A CN105301463A CN201510852324.2A CN201510852324A CN105301463A CN 105301463 A CN105301463 A CN 105301463A CN 201510852324 A CN201510852324 A CN 201510852324A CN 105301463 A CN105301463 A CN 105301463A
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- 239000012212 insulator Substances 0.000 title claims abstract description 29
- 238000005259 measurement Methods 0.000 title abstract description 10
- 210000001015 abdomen Anatomy 0.000 claims abstract description 4
- 230000008054 signal transmission Effects 0.000 claims description 3
- 238000012360 testing method Methods 0.000 abstract description 8
- 238000001514 detection method Methods 0.000 abstract description 2
- 239000013078 crystal Substances 0.000 description 17
- 238000010586 diagram Methods 0.000 description 11
- 238000006243 chemical reaction Methods 0.000 description 10
- 239000003990 capacitor Substances 0.000 description 5
- 238000009413 insulation Methods 0.000 description 4
- 229910052573 porcelain Inorganic materials 0.000 description 3
- 238000000034 method Methods 0.000 description 2
- 230000000694 effects Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000003780 insertion Methods 0.000 description 1
- 230000037431 insertion Effects 0.000 description 1
- 239000004973 liquid crystal related substance Substances 0.000 description 1
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Abstract
The invention relates to the technical field of power system insulator testing and particularly to an unmanned plane insulator zero measurement device. The device mainly solves the problems in the prior art that spark gap tests are low in efficiency, high in missed and error detection rates and poor in safety. The device comprises an unmanned plane, a remote controller matching the unmanned plane for usage, a motor, two coaxial line reels, two measurement line coils, and a meter. The motor and the two coaxial line reels are all installed on the belly of the unmanned plane. An output shaft of the motor is connected with a shaft of the two coaxial line reels, and the two measurement line coils are wound around the two line reels respectively. Two measurement pins of the meter are connected with the two measurement line coils respectively. The meter is in wireless connection with a receiver and transmits measured signals to the receiver which displays the results.
Description
Technical field
The invention belongs to the sub-detection technique field of power system insulation, be specifically related to a kind of unmanned plane insulator zero device.
Background technology
Insulator chain, along with exposing to the weather and term Voltage effect open air, may have indivedual porcelain vase on-insulated.This porcelain insulator is destroyed, insulation resistance is close to 0, the magnitude of voltage that porcelain vase string is born is also close to 0, therefore be called as " zero resistance insulator ", " zero resistance insulator " finds not in time and changes and wire voltage just may occur puncture all good insulators and the situation causing single-phase earthing, affects normal power supply.Traditional sparking distance testing apparatus needs artificial upper tower, hot line job, not only dangerous but also to measure efficiency low, undetected false retrieval more problems.
Summary of the invention
The present invention, mainly for the problem adopting at present sparking distance test to there is the high and poor stability of low, the undetected fallout ratio of efficiency, provides a kind of unmanned plane insulator zero device.
The present invention is the technical scheme taked that solves the problem:
A kind of unmanned plane insulator zero device, comprise unmanned plane, the telepilot used is mated with unmanned plane, wherein also comprise motor, two coaxial wire spool, two volume slotted line and measuring appliances, described motor and two coaxial wire spools are all arranged on the belly of unmanned plane, the output shaft of motor is connected with the axle of two coaxial wire spools, two volume slotted lines are wrapped on two wire spools respectively, two surveyingpins of measuring appliance are connected with two slotted lines respectively, and the signal transmission of measurement shows to receiver by described measuring appliance and receiver wireless connections.
The present invention evenly arranges multiple connecting link between two volume slotted lines.
Be provided with metering circuit in measuring appliance of the present invention, in receiver, be provided with receiving circuit.
Described measuring appliance metering circuit comprises collecting part, conversion edit segment, wireless receiving and dispatching penetrates part and power unit composition, described collecting part is by input terminal and resistance R1-R7, electric capacity C1 forms, No. 3 of input terminal are connected with two slotted lines respectively with No. 4 ports, No. 1 of input terminal is all connected with one end of resistance R1 with No. 2 ports, the other end of resistance R1 is connected with one end of resistance R3 with one end of resistance R2, the other end of resistance R2 is connected with one end of resistance R4 with the other end of resistance R3, the other end of resistance R3 is connected with one end of resistance R5 with the other end of resistance R2, the other end of resistance R4 is connected with one end of electric capacity C1 with the other end of resistance R5, the other end of resistance R5 and the other end of resistance R4, one end of resistance R6 is connected with one end of resistance R7, ground connection after the other end of electric capacity C1 is connected with the other end of resistance R6, the other end of resistance R7 is connected with the P0.2 port of single-chip microcomputer U1,
Described conversion edit segment is by programming terminal PRG, single-chip microcomputer U1, resistance R8-R11, electric capacity C2-C4 and crystal oscillator X1 forms, No. 1 port of programming terminal PRG and one end of resistance R8, No. 7 ports of single-chip microcomputer U1, No. 8 ports of radio receiving transmitting module and one end of electric capacity C5 are connected, No. 2 ports of programming terminal PRG are connected with No. 3 ports of single-chip microcomputer U1 with one end of resistance R9, the other end of resistance R9 is connected with one end of electric capacity C2 with the other end of resistance R8, the other end ground connection of electric capacity C2, No. 3 ports of programming terminal PRG are connected with No. 17 ports of single-chip microcomputer U1, No. 4 port ground connection of programming terminal PRG, No. 5 port ground connection of single-chip microcomputer U1, No. 10 ports of single-chip microcomputer U1 and one end of resistance R10, one end of resistance R11 is connected, the other end of resistance R10 is connected with No. 1 port of power supply POW, the other end ground connection of resistance R11, No. 11 ports of single-chip microcomputer U1 are connected with one end of resistance R12, No. 15 ports of single-chip microcomputer U1 are connected with one end of electric capacity C4 with one end of crystal oscillator X1, No. 16 ports of single-chip microcomputer U1 are connected with one end of electric capacity C3 with the other end of crystal oscillator X1, ground connection after the other end of electric capacity C3 is connected with the other end of electric capacity C4, No. 18 ports of single-chip microcomputer U1 are connected with No. 1 port of radio receiving transmitting module T1, No. 19 ports of single-chip microcomputer U1 are connected with No. 2 ports of radio receiving transmitting module T1, other ports of single-chip microcomputer U1 are empty angle,
Described wireless receiving and dispatching is penetrated part and is comprised radio receiving transmitting module T1, electric capacity C5-6, No. 1 port of radio receiving transmitting module T1 is connected with No. 18 ports of single-chip microcomputer U1, No. 2 ports of radio receiving transmitting module T1 are connected with No. 19 ports of single-chip microcomputer U1, No. 6 port ground connection of radio receiving transmitting module T1, No. 7 ports of radio receiving transmitting module T1 are connected with one end of electric capacity C6 with No. 1 port of power supply POW, the other end ground connection of electric capacity C6, No. 8 ports of radio receiving transmitting module T1 are connected with one end of electric capacity C5 with No. 1 port of programming terminal PRG, the other end ground connection of electric capacity C5.
Receiving circuit in described receiver 9 comprises receiver editor terminal part, receiver conversion edit segment, receiver transceiver module part, display section, display driving part, reseting module, receiver crystal oscillator module, filter capacitor module and indicating lamp module composition, described receiver editor terminal part is editor's terminals P 3, editor's No. 1 port of terminals P 3 is connected with No. 1 port of power supply POW2, No. 4 port ground connection of editor's terminals P 3;
Described receiver conversion edit segment is made up of single-chip microcomputer U2 and electric capacity C7-10, No. 2 ports of single-chip microcomputer U2 are connected with reset key, No. 6 port ground connection of single-chip microcomputer U2, No. 7 ports of single-chip microcomputer U2 are connected with one end of electric capacity C8 with one end of electric capacity C7, ground connection after the other end of electric capacity C7 is connected with the other end of electric capacity C8, No. 8 ports of single-chip microcomputer U2 are connected with one end of electric capacity C10 with one end of electric capacity C9, ground connection after the other end of electric capacity C9 is connected with the other end of electric capacity C10, No. 9 ports of single-chip microcomputer U2 are connected with one end of resistance R26, No. 10 ports of single-chip microcomputer U2 are connected with one end of resistance R27, No. 11 ports of single-chip microcomputer U2 are connected with one end of resistance R28, No. 21 ports of single-chip microcomputer U2 are connected with No. 2 ports of radio receiving transmitting module T2 with one end of resistance R17, No. 22 ports of single-chip microcomputer U2 and one end of resistance R16, No. 1 port of radio receiving transmitting module T2 is connected, No. 25 ports of single-chip microcomputer U2 are connected with No. 6 ports of driver DISP with one end of resistance R18, No. 26 ports of single-chip microcomputer U2 are connected with No. 7 ports of driver DISP with one end of resistance R19, No. 27 ports of single-chip microcomputer U2 are connected with No. 8 ports of driver DISP with one end of resistance R20, No. 28 ports of single-chip microcomputer U2 are connected with one end of resistance R21, No. 29 ports of single-chip microcomputer U2 are connected with one end of resistance R22, No. 30 ports of single-chip microcomputer U2 are connected with one end of resistance R23, No. 31 ports of single-chip microcomputer U2 are connected with one end of resistance R24, No. 32 ports of single-chip microcomputer U2 are connected with one end of resistance R25, other ports of single-chip microcomputer U2 are empty pin,
Described receiver transceiver module part is by radio receiving transmitting module T2, electric capacity C15, power supply POW2, diode D1 and K switch 1 form, No. 1 port of radio receiving transmitting module T2 is connected with No. 22 ports of single-chip microcomputer U2, No. 2 ports of radio receiving transmitting module T2 are connected with No. 21 ports of single-chip microcomputer U2, No. 6 port ground connection of radio receiving transmitting module T2, No. 7 ports of radio receiving transmitting module T2 are connected with No. 1 port of power supply POW2, No. 8 ports of radio receiving transmitting module T2 are connected with one end of electric capacity C15 with No. 1 port of power supply POW2, ground connection after No. 2 ports of power supply POW2 are connected with the other end of electric capacity C15, one end of diode D1 is connected with 3 ends of power supply POW2, the other end of diode D1 is connected with one end of K switch 1, the other end of K switch 1 is No. 1 port of power supply POW2,
Described display section by R16-R28 totally 13 resistance form, be connected with No. 1 port of editor's terminals P 3 after the other end of R16-R28 is connected;
Described display driving part is made up of driver DISP and resistance R15, No. 1 port ground connection of driver DISP, No. 2 ports of driver DISP are connected with No. 1 port of power supply POW2 by resistance R15, No. 3 port ground connection of driver DISP, No. 4 ports of driver DISP are connected with No. 1 port of power supply POW2, No. 6 ports of driver DISP are connected with one end of resistance R18, No. 7 ports of driver DISP are connected with one end of resistance R19, No. 8 ports of driver DISP are connected with one end of resistance R20, other ports of driver DISP are empty pin,
Described reseting module is made up of resistance R13-R14 and electric capacity C11-C12, one end of resistance R14 is connected with No. 1 port of power supply POW2, the other end of resistance R14 is connected with one end of electric capacity C12 with one end of reset key, resistance R13, the other end ground connection of electric capacity C12, the other end of resistance R13 is connected with reset key one end with electric capacity C11, the other end ground connection of electric capacity C11;
Described receiver crystal oscillator module is made up of crystal oscillator X2 and electric capacity C13-C14, one end of crystal oscillator X2 is connected with one end of electric capacity C13 with No. 4 ports of single-chip microcomputer U2, the other end ground connection of electric capacity C13, the other end of crystal oscillator X2 is connected with one end of electric capacity C14 with No. 5 ports of single-chip microcomputer U2, the other end ground connection of electric capacity C14;
Described filter capacitor module is made up of four electric capacity C15-C18 in parallel, and after electric capacity C15-C18 parallel connection, one end is connected with No. 1 port of power supply POW2, the other end ground connection after electric capacity C15-C18 parallel connection.
Described indicating lamp module comprises resistance R12 and pilot lamp LED, and one end of resistance R12 is connected with No. 11 ports of single-chip microcomputer U1, and the other end of resistance R12 is connected with one end of pilot lamp LED, the other end ground connection of pilot lamp LED.
The present invention adopts technique scheme, by the potential difference (PD) at the monolithic insulator two ends in measuring appliance surveying work, through inner high-tension resistive dividing potential drop, potential difference signal is input to inner Acquisition Circuit, digital signal is converted to by A/D converter, launch after digital circuit coded treatment, after wireless insulator receiver receives, digital signal is converted to through digital circuit decoding, finally demonstrate magnitude of voltage by liquid crystal display, if when the potential difference (PD) recording certain a slice insulator is O, then this sheet insulator is zero resistance insulator, if the potential difference (PD) recording certain a slice insulator lower than standard value see attached list 50% time, illustrate that this sheet insulator is Faulty insulator.According to surveyed Plotting data insulator spread voltage curve, be used for confirming further to judge Faulty insulator.
Pick-up unit of the present invention has carried out a large amount of field tests, and result meets national DL/T626-1997 standard.This instrument is for testing the spread voltage value of 35 ~ 1000KV suspended insulator or test in laboratory suspended insulator, effectively can find the hidden fault of interior insulator, improve network system reliability of operation, also improve the work efficiency that line work personnel carry out live testing.And there is the features such as the mono-﹑ of Ti Ji little ﹑ Chong Liang Qing ﹑ Shi Jian is easy to carry, the three ball board high pressure damp proof insulation bars that the insulating bar of adapted selects munitions factory to produce, there is the features such as the high insulation of the Fang Chao ﹑ Wen of Nai Gao ﹑ Kang Chong Ji ﹑ Kang Wan ﹑.
Accompanying drawing explanation
Fig. 1 is structural representation of the present invention;
Fig. 2 is measuring appliance metering circuit collecting part circuit diagram of the present invention;
Fig. 3 is measuring appliance metering circuit of the present invention conversion edit segment circuit diagram;
Fig. 4 is that measuring appliance metering circuit wireless receiving and dispatching of the present invention penetrates partial circuit figure;
Fig. 5 is the circuit diagram of measuring appliance metering circuit power supply of the present invention;
Fig. 6 is receiver receiving circuit receiver editor terminal part of the present invention circuit diagram;
Fig. 7 is receiver receiving circuit receiver of the present invention conversion edit segment circuit diagram;
Fig. 8 is receiver receiving circuit receiver transceiver module partial circuit figure of the present invention;
Fig. 9 is receiver receiving circuit display section of the present invention circuit diagram;
Figure 10 is receiver receiving circuit display driving part circuit diagram of the present invention;
Figure 11 is receiver receiving circuit reseting module circuit diagram of the present invention;
Figure 12 is receiver receiving circuit receiver crystal oscillator module circuit diagram of the present invention;
Figure 13 is receiver receiving circuit filter capacitor module circuit diagram of the present invention;
Figure 14 is receiver receiving circuit indicating lamp module circuit diagram of the present invention.
Embodiment
Embodiment 1
A kind of unmanned plane insulator zero device, as shown in Figure 1, comprise unmanned plane 1, the telepilot 2 used is mated with unmanned plane, wherein also comprise motor 3, two coaxial wire spools 4, two volume slotted lines 5 and measuring appliance 6, described motor 3 and two coaxial wire spools 4 are all arranged on the belly of unmanned plane, the output shaft of motor 3 is connected with the axle of two coaxial wire spools 4, two volume slotted lines 5 are wrapped on two wire spools 4 respectively, between two volume slotted lines 5, multiple connecting link 7 is evenly set, two surveyingpins of measuring appliance 6 are connected with two slotted lines 5 respectively, the signal transmission of measurement shows to receiver 9 with receiver 9 wireless connections by described measuring appliance 6.
Be provided with metering circuit in measuring appliance 6 of the present invention, in receiver 9, be provided with receiving circuit.
Described measuring appliance metering circuit comprises collecting part, conversion edit segment, wireless receiving and dispatching penetrates part and power unit composition, collecting part described is as shown in Figure 2 by input terminal 8 and resistance R1-R7, electric capacity C1 forms, No. 3 of input terminal 8 are connected with two slotted lines 5 respectively with No. 4 ports, No. 1 of input terminal 8 is all connected with one end of resistance R1 with No. 2 ports, the other end of resistance R1 is connected with one end of resistance R3 with one end of resistance R2, the other end of resistance R2 is connected with one end of resistance R4 with the other end of resistance R3, the other end of resistance R3 is connected with one end of resistance R5 with the other end of resistance R2, the other end of resistance R4 is connected with one end of electric capacity C1 with the other end of resistance R5, the other end of resistance R5 and the other end of resistance R4, one end of resistance R6 is connected with one end of resistance R7, ground connection after the other end of electric capacity C1 is connected with the other end of resistance R6, the other end of resistance R7 is connected with the P0.2 port of single-chip microcomputer U1,
Conversion edit segment described is as shown in Figure 3 by programming terminal PRG, single-chip microcomputer U1, resistance R8-R11, electric capacity C2-C4 and crystal oscillator X1 forms, No. 1 port of programming terminal PRG and one end of resistance R8, No. 7 ports of single-chip microcomputer U1, No. 8 ports of radio receiving transmitting module and one end of electric capacity C5 are connected, No. 2 ports of programming terminal PRG are connected with No. 3 ports of single-chip microcomputer U1 with one end of resistance R9, the other end of resistance R9 is connected with one end of electric capacity C2 with the other end of resistance R8, the other end ground connection of electric capacity C2, No. 3 ports of programming terminal PRG are connected with No. 17 ports of single-chip microcomputer U1, No. 4 port ground connection of programming terminal PRG, No. 5 port ground connection of single-chip microcomputer U1, No. 10 ports of single-chip microcomputer U1 and one end of resistance R10, one end of resistance R11 is connected, the other end of resistance R10 is connected with No. 1 port of power supply POW, the other end ground connection of resistance R11, No. 15 ports of single-chip microcomputer U1 are connected with one end of electric capacity C4 with one end of crystal oscillator X1, No. 16 ports of single-chip microcomputer U1 are connected with one end of electric capacity C3 with the other end of crystal oscillator X1, ground connection after the other end of electric capacity C3 is connected with the other end of electric capacity C4, No. 18 ports of single-chip microcomputer U1 are connected with No. 1 port of radio receiving transmitting module T1, No. 19 ports of single-chip microcomputer U1 are connected with No. 2 ports of radio receiving transmitting module T1, other ports of single-chip microcomputer U1 are empty angle,
Wireless receiving and dispatching described is as shown in Figure 4 penetrated part and is comprised radio receiving transmitting module T1, electric capacity C5-6, No. 1 port of radio receiving transmitting module T1 is connected with No. 18 ports of single-chip microcomputer U1, No. 2 ports of radio receiving transmitting module T1 are connected with No. 19 ports of single-chip microcomputer U1, No. 6 port ground connection of radio receiving transmitting module T1, No. 7 ports of radio receiving transmitting module T1 are connected with one end of electric capacity C6 with No. 1 port of power supply POW, the other end ground connection of electric capacity C6, No. 8 ports of radio receiving transmitting module T1 are connected with one end of electric capacity C5 with No. 1 port of programming terminal PRG, the other end ground connection of electric capacity C5.
Receiving circuit in described receiver 9 comprises receiver editor terminal part, receiver conversion edit segment, receiver transceiver module part, display section, display driving part, reseting module, receiver crystal oscillator module, filter capacitor module and indicating lamp module composition, receiver editor terminal part described is as shown in Figure 6 editor's terminals P 3, editor's No. 1 port of terminals P 3 is connected with No. 1 port of power supply POW2, No. 4 port ground connection of editor's terminals P 3;
Receiver conversion edit segment described is as shown in Figure 7 made up of single-chip microcomputer U2 and electric capacity C7-10, No. 2 ports of single-chip microcomputer U2 are connected with reset key, No. 6 port ground connection of single-chip microcomputer U2, No. 7 ports of single-chip microcomputer U2 are connected with one end of electric capacity C8 with one end of electric capacity C7, ground connection after the other end of electric capacity C7 is connected with the other end of electric capacity C8, No. 8 ports of single-chip microcomputer U2 are connected with one end of electric capacity C10 with one end of electric capacity C9, ground connection after the other end of electric capacity C9 is connected with the other end of electric capacity C10, No. 9 ports of single-chip microcomputer U2 are connected with one end of resistance R26, No. 10 ports of single-chip microcomputer U2 are connected with one end of resistance R27, No. 11 ports of single-chip microcomputer U2 are connected with one end of resistance R28, No. 21 ports of single-chip microcomputer U2 are connected with No. 2 ports of radio receiving transmitting module T2 with one end of resistance R17, No. 22 ports of single-chip microcomputer U2 and one end of resistance R16, No. 1 port of radio receiving transmitting module T2 is connected, No. 25 ports of single-chip microcomputer U2 are connected with No. 6 ports of driver DISP with one end of resistance R18, No. 26 ports of single-chip microcomputer U2 are connected with No. 7 ports of driver DISP with one end of resistance R19, No. 27 ports of single-chip microcomputer U2 are connected with No. 8 ports of driver DISP with one end of resistance R20, No. 28 ports of single-chip microcomputer U2 are connected with one end of resistance R21, No. 29 ports of single-chip microcomputer U2 are connected with one end of resistance R22, No. 30 ports of single-chip microcomputer U2 are connected with one end of resistance R23, No. 31 ports of single-chip microcomputer U2 are connected with one end of resistance R24, No. 32 ports of single-chip microcomputer U2 are connected with one end of resistance R25, other ports of single-chip microcomputer U2 are empty pin,
Receiver transceiver module part described is as shown in Figure 8 by radio receiving transmitting module T2, electric capacity C15, power supply POW2, diode D1 and K switch 1 form, No. 1 port of radio receiving transmitting module T2 is connected with No. 22 ports of single-chip microcomputer U2, No. 2 ports of radio receiving transmitting module T2 are connected with No. 21 ports of single-chip microcomputer U2, No. 6 port ground connection of radio receiving transmitting module T2, No. 7 ports of radio receiving transmitting module T2 are connected with No. 1 port of power supply POW2, No. 8 ports of radio receiving transmitting module T2 are connected with one end of electric capacity C15 with No. 1 port of power supply POW2, ground connection after No. 2 ports of power supply POW2 are connected with the other end of electric capacity C15, one end of diode D1 is connected with 3 ends of power supply POW2, the other end of diode D1 is connected with one end of K switch 1, the other end of K switch 1 is No. 1 port of power supply POW2,
Display section described as shown in Figure 9 by R16-R28 totally 13 resistance form, be connected with No. 1 port of editor's terminals P 3 after the other end of R16-R28 is connected;
Display driving part described is as shown in Figure 10 made up of driver DISP and resistance R15, No. 1 port ground connection of driver DISP, No. 2 ports of driver DISP are connected with No. 1 port of power supply POW2 by resistance R15, No. 3 port ground connection of driver DISP, No. 4 ports of driver DISP are connected with No. 1 port of power supply POW2, No. 6 ports of driver DISP are connected with one end of resistance R18, No. 7 ports of driver DISP are connected with one end of resistance R19, No. 8 ports of driver DISP are connected with one end of resistance R20, other ports of driver DISP are empty pin,
Reseting module described is as shown in figure 11 made up of resistance R13-R14 and electric capacity C11-C12, one end of resistance R14 is connected with No. 1 port of power supply POW2, the other end of resistance R14 is connected with one end of electric capacity C12 with one end of reset key, resistance R13, the other end ground connection of electric capacity C12, the other end of resistance R13 is connected with reset key one end with electric capacity C11, the other end ground connection of electric capacity C11;
Receiver crystal oscillator module described is as shown in figure 12 made up of crystal oscillator X2 and electric capacity C13-C14, one end of crystal oscillator X2 is connected with one end of electric capacity C13 with No. 4 ports of single-chip microcomputer U2, the other end ground connection of electric capacity C13, the other end of crystal oscillator X2 is connected with one end of electric capacity C14 with No. 5 ports of single-chip microcomputer U2, the other end ground connection of electric capacity C14;
Filter capacitor module described is as shown in figure 13 made up of four electric capacity C15-C18 in parallel, and after electric capacity C15-C18 parallel connection, one end is connected with No. 1 port of power supply POW2, the other end ground connection after electric capacity C15-C18 parallel connection.
Indicating lamp module described as shown in figure 14 comprises resistance R12 and pilot lamp LED, and one end of resistance R12 is connected with No. 11 ports of single-chip microcomputer U1, and the other end of resistance R12 is connected with one end of pilot lamp LED, the other end ground connection of pilot lamp LED.
Using method:
The upper cover of 1 ﹑ Unscrew emitter before measuring, flicking switch, after power supply is opened, signal lamp glimmers, and emission measurement normally works, and builds upper cover.
2 ﹑ connect telescopic insulating bar, are pulled out by insulating bar, hold insulating bar, do not exceed the mark that handrail is spacing.
When 3 ﹑ measure, by the two ends of two voltage probe contacts monolithic insulator just at work.
The power switch of 4 ﹑ flicking receiving traps, LCDs has display, illustrates that receiving trap normally works.
5 ﹑ work as emitter has signal to send, first receiving trap identifies the code whether matched, if not being pair code, receiving end is Received signal strength not, signal lamp does not glimmer, and when identification receives the code matched, signal lamp starts flicker, LCDs display measurement value, unit is kilovolt.
6 ﹑ finish using, the power supply of stopping device, keep well and wait for that next time uses.
7 ﹑ in use, if launched or receiving trap display low-voltage, do not affect use, can continue to use.Please charging before using next time.
During 8 ﹑ charging, please charger is inserted 220V AC power, the charging jacks of voltage output plug insertion apparatus.When pilot lamp on charger is red, represents and charge; During for green, represent that charging is full.The general duration of charging is one hour, and long-time charging can not damage device and charger.
Claims (2)
1. a unmanned plane insulator zero device, comprise unmanned plane (1), the telepilot (2) used is mated with unmanned plane, it is characterized in that: also comprise motor (3), two coaxial wire spools (4), two volume slotted lines (5) and measuring appliance (6), described motor (3) and two coaxial wire spools (4) are all arranged on the belly of unmanned plane, the output shaft of motor (3) is connected with the axle of two coaxial wire spools (4), two volume slotted lines (5) are wrapped on two wire spools (4) respectively, two surveyingpins of measuring appliance (6) are connected with two slotted lines (5) respectively, the signal transmission measured shows to receiver (9) by described measuring appliance (6) and receiver (9) wireless connections.
2. unmanned plane insulator zero device according to claim 1, is characterized in that: between two volume slotted lines (5), evenly arrange multiple connecting link (7).
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN106932694A (en) * | 2017-03-16 | 2017-07-07 | 广州供电局有限公司 | Insulator deterioration detecting device |
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